Non-volatile memory interface

ABSTRACT

In an embodiment, a memory interface may send an indication that a request is being sent. The indication may be sent to a non-volatile memory via a point-to-point bus between a memory interface and the non-volatile memory. The memory interface may send the request to the non-volatile memory via the bus. The request may include an address that may be used to identify a location for storing or reading data. The non-volatile memory may acquire the request from the bus and process the request. After processing the request, the non-volatile memory may send an indication to the memory interface that indicates the non-volatile memory has a response to send to the memory interface. The memory interface may grant access to the bus to the non-volatile memory. After being granted access to the bus, the non-volatile memory may send the response to the memory interface.

BACKGROUND

A computing device may include storage that may be used to storeinformation. The information may include, for example, data and/orexecutable instructions. The storage may include a primary storage and asecondary storage. The primary storage may provide, for example, aninternal storage for the processor. The secondary storage may provide,for example, an external storage for the processor. The processor mayaccess the storage via one or more busses. The busses may be used totransfer information between the processor and the storage.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate one or more embodiments describedherein and, together with the description, explain these embodiments. Inthe drawings:

FIG. 1 illustrates a block diagram of an example of a computing device;

FIG. 2 illustrates examples of phases that may be associated withtransactions;

FIG. 3 illustrates an example of a timing diagram that may be associatedwith a read transaction;

FIG. 4 illustrates an example of a timing diagram that may be associatedwith a write transaction;

FIGS. 5A-B illustrate a flow diagram of example acts that may beperformed by a host during a read transaction;

FIGS. 6A-B illustrate a flow diagram of example acts that may beperformed by a client during a read transaction;

FIGS. 7A-B illustrate a flow diagram of example, acts that may beperformed by a host during a write transaction;

FIGS. 8A-B illustrate a flow diagram of example acts that may beperformed by a client during a read transaction; and

FIG. 9 illustrates a block diagram of another example of a computingdevice.

DETAILED DESCRIPTION

The following detailed description refers to the accompanying drawings.The same reference numbers in different drawings may identify the sameor similar elements. Also, the following detailed description does notlimit the invention.

A computing device may include storage that the computing device may useto store information (e.g., data, computer-executable instructions). Thestorage may be volatile and/or non-volatile. A volatile storage may beused to store information that may be lost after power is removed fromthe computing device. A non-volatile storage may be used to storeinformation that is to survive (persist) after power is lost to thecomputing device.

For example, a computing device may contain a central processing unit(CPU) and storage. The storage may include, for example, a volatilememory and a non-volatile memory (NVM). The volatile memory may providestorage for information that may be lost after power is removed from thecomputing device. The NVM, on the other hand, may provide storage forinformation that is to persist after power is removed from the computingdevice. The CPU may retrieve the persisted information from the NVMafter power is restored to the computing device.

A storage may contain one or more memory devices that may be used tostore information. A memory device may comprise one or more arrays wherean array may include one or more memory cells that may be used to storeinformation in the memory device.

A memory cell may be associated with an address. The address may be usedto identify the memory cell. Information may be written into and/or readfrom the memory cell using the address. For example, a memory cell in amemory device may be associated with a particular address (e.g., 0x100).A write transaction may specify the address and data to be written tothe memory cell. The address may be used to identify the memory cell andthe data may be written to the memory cell after it is identified.

A storage may be accessed (e.g., read, written) by issuing a command toa device that may contain the storage. The command may be part of atransaction that may be transferred to the device over a bus. Dataassociated with the command may also be transferred via the bus. The busmay include provisions (e.g., wires) for transferring the command and/orthe data to the device.

For example, a computing device may include a CPU and an NVM. The CPUmay be coupled to the NVM via a bus. The bus may be used to transfercommands and/or data between the CPU and the NVM. The bus may be, forexample, a point-to-point bus that may include one or more wires thatmay be used to transfer the commands and/or data.

A storage may include one or more storage modules. The storage modulesmay contain one or more memory devices contained in the storage.Examples of storage modules may include, but are not limited to, dualin-line memory modules (DIMMs), secure digital (SD) cards, multimediacards (MMC), CompactFlash (CF) cards, memory sticks, and single in-linememory modules (SIMMs).

Techniques described herein may be implemented in a computing device.Examples of computing devices that may implement techniques describedherein may include, but are not limited to, smart phones, tablets,ultrabooks, laptops, mainframes, servers, and desktop computers.

FIG. 1 illustrates a block diagram of an example of a computing device100 that may implement various techniques described herein. Referring toFIG. 1, computing device 100 may include various components such as, forexample, volatile memory 120, processing logic 130, host controller (HC)140, and non-volatile memory 150.

It should be noted that FIG. 1 illustrates an example embodiment ofcomputing device 100. Other embodiments of computing device 100 mayinclude more components or fewer components than the componentsillustrated in FIG. 1. Further, the components may be arrangeddifferently than illustrated in FIG. 1. For example, an embodiment ofcomputing device 100 may include a communications interface that may beused to communicate with a network, such as the Internet. Also, itshould be noted that functions performed by various components containedin other embodiments of computing device 100 may be distributed amongthe components differently than as described herein.

Volatile memory 120 may provide storage for computing device 100. Thestorage may be used to store information, such as, for example, dataand/or computer-executable instructions. The storage may be a high-speedstorage that may implement, for example, a cache memory for computingdevice 100 (e.g., a level-2 (L2) cache). Volatile memory 120 may includeone or more devices, such as, for example, memory devices that may beused to store the information.

Non-volatile memory 150 may also provide storage for computing device100. The storage may be, for example, slower and have a higher storagecapacity than volatile memory 120. The storage may be used to storeinformation. The information may be stored on one or more devicescontained in non-volatile memory 150. The devices may include, forexample, one or more memory devices.

A volatile memory device may be a memory device that may loseinformation stored in the memory device when power is removed from thememory device. A non-volatile memory device may be a memory device thatmay retain information stored in the memory device when power is removedfrom the memory device. Examples of memory devices include dynamic RAM(DRAM) devices, flash memory devices, static RAM (SRAM) devices,zero-capacitor RAM (ZRAM) devices, twin transistor RAM (TTRAM) devices,read-only memory (ROM) devices, ferroelectric transistor RAM (FeTRAM)devices, magneto-resistive RAM (MRAM) devices, three dimensional (3D)cross point memory devices (e.g., phase change memory (PCM) devices),nanowire-based devices, resistive RAM (RRAM) devices, serialelectrically erasable programmable ROM (SEEPROM) devices, spin transfertorque (STT) MRAM devices, and serial flash devices.

Processing logic 130 may include logic for interpreting, executing,and/or otherwise processing information. The information may be storedin, for example, volatile memory 120 and/or non-volatile memory 150. Theinformation may include, for example, data and/or computer-executableinstructions.

Processing logic 130 may include a variety of heterogeneous hardware.For example, the hardware may include some combination of one or moreprocessors, microprocessors, field programmable gate arrays (FPGAs),application specific instruction set processors (ASIPs), applicationspecific integrated circuits (ASICs), complex programmable logic devices(CPLDs), graphics processing units (GPUs), and/or other types ofprocessing logic that may, for example, interpret, execute, manipulate,and/or otherwise process the information. Processing logic 130 maycomprise a single core or multiple cores.

Busses 160, 170, 180, and 190 may be point-to-point busses. The busses160, 170, 180, and 190 may include electrical conductors (e.g., wires)that may be used to carry various signals between the components. Thesignals may include, for example, control signals and/or data. Forexample, bus 190 may be a point-to-point bus that may include aplurality of wires that may be used to carry signals betweennon-volatile memory interface (NMI) 146 and non-volatile memory 150. Thesignals may include various control signals and data. The signals may becarried by separate wires. For example, a first wire may be used tocarry request and data information between the NMI 146 and thenon-volatile memory. A second wire may be used to carry strobeinformation that may be used to acquire (e.g., read, receive) therequest and data information. A third wire may be used to indicatewhether the non-volatile memory 150 has been granted ownership of thefirst and second wires in order to transfer information from thenon-volatile memory 150 to the NMI 146, and so on.

HC 140 may include logic that may enable information to be transferredbetween various components in computing device 100. The components mayinclude, for example, volatile memory 120, processing logic 130 and/ornon-volatile memory 150. Information may be transferred between thecomponents via busses 160, 170, 180, and 190, which may couple thecomponents with HC 140.

HC 140 may include logic that may be used as interfaces between variouscomponents in computing device 100. The interfaces may enableinformation to be exchanged (e.g., transferred) between the components.The interfaces may include, for example, a volatile memory interface(VMI) 142 and NMI 146. The VMI 142 may be used to interface processinglogic 130 with volatile memory 120. The NMI 146 may be used to interfaceprocessing logic 130 with non-volatile memory 150.

VMI 142 may contain logic that may enable information to be communicated(e.g., transferred) between volatile memory 120 and processing logic 130via busses 160 and 170. Specifically, VMI 142 may contain logic that mayenable information to be communicated between VMI 142 and volatilememory 120 via bus 160. Moreover, VMI 142 may contain logic that mayenable information to be communicated between processing logic 130 andVMI 142 via the bus 170. The information may include, for example,commands and/or data. Examples of logic that may be included in VMI 142may include state machines, bus transceivers, registers, and/or otherlogic.

NMI 146 may contain logic that may enable information to be communicatedbetween non-volatile memory 150 and processing logic 130 via busses 180and 190. Specifically, NMI 146 may contain logic that may be used tocommunicate information between NMI 146 and processing logic 130 via bus180. Moreover, NMI 146 may contain logic that may be used to communicateinformation between non-volatile memory 150 and NMI 146 via bus 190.Logic that may be contained in NMI 146 that may be included in NMI 146may include, for example, state machines, bus transceivers, registers,and/or other logic.

The information may include, for example, requests and/or data. Therequests may include command information (e.g., read command, writecommand) and/or address information (e.g., address to be read, addressto be written). The information may be communicated using transactions.

A transaction may be used to communicate information between twoentities over a bus. For example, information may communicated betweenNMI 146 and non-volatile memory 150 via bus 190 using transactions.Information communicated using a transaction may include, for example,request, data, and/or response information.

A transaction may be of a certain type. For example, a transaction maybe a write transaction or a read transaction. A write transaction may beused, for example, to write information to storage, such as tonon-volatile memory 150. A read transaction may be used, for example, toread information from storage, such as from non-volatile memory 150.

A transaction may include a number of phases. For example, a transactionmay include a request phase, a data phase, and/or a response phase. Aphase may be accompanied with certain types of information that may betransferred between entities during the phase. For example, during arequest phase, command and/or address information may be transferredbetween the entities.

FIG. 2 illustrates example phases that may be associated with a readtransaction and a write transaction that may be transferred betweenentities, such as NMI 146 and non-volatile memory 150, via a bus, suchas bus 190. Referring to FIG. 2, reference numeral 220 includes (1) atimeline and (2) information that may be transferred during the readtransaction. Reference number 260 includes (1) a timeline and (2)information that may be transferred at phases that may be associatedwith the write transaction.

The read transaction may include a request phase, a data phase, and aresponse phase. The request phase may occur at time 230 a. The requestphase may include transferring a request 240 a between the entities viathe bus. The request 240 a may include, for example, a preamble, acommand, and/or an address. The command may identify an operation (inthis example a read operation) that is to be performed. The address mayidentify a location that is to be read.

The preamble may be used to prepare to acquire the request 240 a.Preparing may include, for example, using the preamble to train toacquire the request 240 a from the bus. The preamble may include apredefined sequence of bits that may be used to perform the training.

For example, suppose the entities include NMI 146 and non-volatilememory 150, and the bus includes bus 190. During the request phase,request 240 a may be sent from NMI 146 to non-volatile memory 150 viabus 190. The request 240 a may include a preamble, command, and anaddress. The preamble may include a predefined sequence of bits that maybe used by the non-volatile memory 150 to prepare to receive the commandand address from bus 190. The command may identify a read operation thatis to be performed by the non-volatile memory 150. The address mayidentify a location in the non-volatile memory 150 that is to be read.

The data phase may begin after the request phase. The data phase mayinclude a time 230 b where an entity may process the request. Forexample, during the data phase, the non-volatile memory 150 may processthe above request. Here, processing may include, for example, readingdata 240 b from the non-volatile memory 150 at the location identifiedby the address.

The data phase may also include a time 230 c when the data 240 b istransferred between the entities. For example, after reading the data240 b, the data 240 b may be transferred via bus 190 from thenon-volatile memory 150 to the NMI 146.

At time 230 d, the request may enter the response phase. The responsephase may include sending a response 240 c to the request. The response240 c may provide an indication that the request has been processed. Theresponse 240 c may be preceded by a preamble that may be used to prepareto acquire the response 240 c. The preamble may be used to prepare toacquire the response 240 c. Preparing may include, for example, usingthe preamble to train to acquire the response 240 c from the bus. Thepreamble may include a predefined sequence of bits that may be used toperform the training.

For example, during the response phase a response 240 c and preamble maybe sent from the non-volatile memory 150 via the bus 190 to the NMI 146.The response 240 c may provide an indication to the NMI 146 that therequest has been processed by the non-volatile memory 150. The response240 c may include, for example, a status that may be associated with theread request. The status may indicate whether a read operation performedat the non-volatile memory 150 was performed successfully. The response240 c may be preceded by the preamble. NMI 146 may use the preamble toprepare to receive the response 240 c from bus 190. Preparing mayinclude training, such as described above.

Referring now to reference numeral 260, the write transaction may alsoinclude a request phase, a data phase, and a response phase. At time 270a, the request phase may include a request 280 a. The request 280 a maycontain, for example, a preamble, a command, and/or an address. Thepreamble may be used to receive the command and/or address. The commandmay indicate that a write operation is to be performed and the addressmay identify a location where data is to be written.

For example, suppose the entities include NMI 146 and non-volatilememory 150, and the bus includes bus 190. During the request phase,request 280 a may be sent from NMI 146 to non-volatile memory 150 viabus 190. The request 280 a may include a preamble, command, and anaddress. The preamble may be used by the non-volatile memory 150 toprepare to receive the command and address. Preparing may includetraining, such as described above. The command may identify a writeoperation that is to be performed by the non-volatile memory 150. Theaddress may identify a location in the non-volatile memory 150 that isto be written.

The data phase may occur after the request phase. During the data phase,data 280 b to be written may be transferred between the entities, asindicated at time 270 b. Also, during the data phase, at time 270 c, thedata may be written to the location identified, for example, in therequest 280 a.

For example, during the data phase data 280 b may be transferred fromthe NMI 146 to the non-volatile memory 150 via bus 190. After receivingthe data 280 b, non-volatile memory 150 may write the data to a locationin non-volatile memory 150 that may be identified using the addresscontained in request 280 a.

The response phase may follow the data phase as indicated at time 270 d.During the response phase, a response 280 c may be transferred betweenthe entities. The response 280 c may include, for example, a statusassociated with the write request. The status may indicate, for example,whether the write request was successfully completed.

For example, non-volatile memory 150 may generate response 280 c thatmay contain a status that may indicate whether the write operation wassuccessful. During the response phase, non-volatile memory 150 maytransfer the response 280 c via bus 190 to NMI 146.

Various signals may be transferred between the NMI 146 and thenon-volatile memory 150 via bus 190. Bus 190 may be a connected bus(e.g., a point-to-point bus) and each of the signals may be carried, forexample, on separate connections (e.g., electrically conductive wires,optical connections) that may be included in bus 190. The signals mayinclude, for example, signals listed in the following table.

Signal Name Size Direction Description DQ  8 or 16 Bidirectional DataDQS 2 or 4 Bidirectional Data strobe differential pair ACT 1Unidirectional from NMI transmission indication NMI to non-volatilememory RGRANT 1 Unidirectional from NMI grants DQ and DQS NMI tonon-volatile ownership to non-volatile memory memory RQRDY 1Unidirectional from NMI request ready NMI to non-volatile memory RRDY 1Unidirectional from Non-volatile memory non-volatile response readymemory to NMI

Note that the above table provides examples of signals that may betransferred between NMI 146 and non-volatile memory 150. Other signalsmay also be transferred between NMI 146 and non-volatile memory 150 via,for example, bus 190. These signals may include, for example, a signalthat may be used to reset an operation of the NMI 146 and/ornon-volatile memory 150, a signal that may provide a reference forimpedance calibration and/or check bit signals that may provide errordetection and/or correction of information transferred, for example,over bus 190.

Still other signals may include, for example, signals that may be usedfor power management. For example, a signal that may be included thatmay be used by the NMI 146 to direct the non-volatile memory 150 toenter into a low power state. Another signal may be included that may beused, for example, by the NMI 146 to direct the non-volatile memory 150to exit a low power state.

Note that wires that carry signals over bus 190 may be repurposed tocarry certain signals based on, for example, a state of non-volatilememory 150 and/or NMI 146. For example, wires carrying ACT and RRDY maybe repurposed for use in managing a power state associated withnon-volatile memory 150, such as described above.

Signals transferred between non-volatile memory 150 and NMI 146 may beasserted and deasserted at various times to provide various indicationsduring a transaction. FIG. 3 illustrates a timing diagram 300 of anexample operation of signals during a read transaction between, forexample, NMI 146 and non-volatile memory 150. The signals may betransferred between non-volatile memory 150 and the NMI 146 via bus 190.

Referring to FIG. 3, time 330 a may represent a state of the signalsprior to the read transaction. Specifically, at time 330 a, theabove-described ACT, RGRANT, RQRDY, and RRDY signals may be deasserted.In addition, the above-described DQ and DQS may be in a high-impedancestate, as indicated by broken lines in diagram 300.

At time 330 b, NMI 146 may assert the ACT signal to indicate to thenon-volatile memory 150 that the NMI 146 has a request to send.Asserting ACT may indicate a request phase of the read transaction hasbeen entered. Non-volatile memory 150 may detect that ACT is assertedand prepare to receive a preamble associated with the request on DQS. Attime 330 c, NMI 146 may begin to transfer the preamble on DQS.Non-volatile memory 150 may receive the preamble and prepare to receivethe request from NMI 146. Preparing may include training, such asdescribed above.

At times 330 d and 330 e, NMI 146 may transfer the request onto DQ. Inaddition, NMI 146 may provide a strobe signal on DQS that thenon-volatile memory 150 may use to acquire the request from DQ.Non-volatile memory 150 may acquire the strobe signal and use the strobesignal use to acquire the request from DQ during times 330 d and 330 e.

At time 330 e, NMI 146 may deassert RQRDY. Non-volatile memory 150 maydetect that NMI 146 has deasserted RQRDY and discontinue acquiring therequest from DQ. Moreover, at times 330 f and 330 g, NMI 146 maytransfer a post-amble over DQS to the non-volatile memory 150. Thenon-volatile memory 150 may acquire the post-amble and determine thatthe request phase has been exited.

At time 330 h, non-volatile memory 150 may process the request. Here,processing may include determining the request is a read request andreading data from the non-volatile memory 150 at a location identifiedin the request.

After the data is read, non-volatile memory 150 may assert RRDY, asindicated at time 330 i, to indicate to the NMI 146 that non-volatilememory 150 is ready to send information to the NMI 146. The informationmay include, for example, data that was read from the non-volatilememory 150. Here, asserting RRDY may indicate entering a data phase ofthe read transaction.

NMI 146 may determine that RRDY has been asserted and assert RGRANT tosend an indication to non-volatile memory 150 that ownership of DQ hasbeen granted, as indicated at time 330 j.

After detecting that RGRANT has been asserted and determining based onRGRANT being asserted that the non-volatile memory 150 has been grantedownership of DQ, the non-volatile memory 150 may begin transferring apreamble on DQS as indicated at time 330 k. NMI 146 may acquire thepreamble and prepare to receive the data on DQ. Preparing may includetraining, such as described above. At times 330 m and 330 n, thenon-volatile memory 150 may transfer the data and associated strobeinformation onto DQ and DQS, respectively. NMI 146 may use the strobeinformation to acquire the data from DQ.

At time 330 o, non-volatile memory 150 may deassert RRDY to indicatethat the data phase has been exited and that a response phase of theread transaction has been entered. After deasserting RRDY, thenon-volatile memory 150 may transfer response information on DQ. Theresponse information may include, for example, a status associated withthe request. The status may indicate, for example, whether the requestwas successfully processed by the non-volatile memory 150. NMI 146 mayacquire the response information from DQ and process it. Here,processing may include, for example, determining whether the request wassuccessfully processed by the non-volatile memory 150.

At times 330 o and 330 p, the non-volatile memory 150 may transfer apost-amble onto DQS. NMI 146 may acquire the post-amble and determinethat the response phase has been exited. After determining the responsephase has been exited, NMI 146 may deassert the RGRANT signal, asindicated at time 330 q.

FIG. 4 illustrates a timing diagram 400 of an example operation ofsignals during a write transaction between, for example, NMI 146 andnon-volatile memory 150. The signals may be transferred between NMI 146and non-volatile memory 150 via bus 190.

Referring to FIG. 4, time 430 a may represent a state of the signalsprior to the write transaction. Specifically, at time 430 a, theabove-described ACT. RGRANT, RQRDY, and RRDY signals may be deasserted.In addition, the above-described DQ and DQS may be in a high-impedancestate, as indicated by broken lines in diagram 400.

At time 430 b, NMI 146 may assert the ACT signal to indicate to thenon-volatile memory 150 that the NMI 146 has a request to send.Asserting ACT may indicate a request phase of the write transaction hasbeen entered. Non-volatile memory 150 may detect that ACT is assertedand prepare to acquire a preamble associated with the request on DQS. Attime 430 c. NMI 146 may begin to transfer the preamble on DQS.Non-volatile memory 150 may acquire the preamble and prepare to acquirethe request from NMI 146. Preparing may include training using thepreamble, such as described above.

At times 430 d and 430 e, NMI 146 may transfer the request onto DQ. Therequest may include a command and an address. The command may identifythe request as a write request and the address may identify a locationin non-volatile memory 150 that is to be written with data. NMI 146 mayprovide a strobe signal on DQS that the non-volatile memory 150 may useto acquire the request from DQ. Non-volatile memory 150 may receive thestrobe signal and use the strobe signal to acquire the request from DQduring times 430 d and 430 e.

At time 430 f. NMI 146 may deassert RQRDY. Non-volatile memory 150 maydetect that NMI 146 has deasserted RQRDY and discontinue acquiring therequest from DQ. Note that RQRDY may be asserted for a time that therequest is being transferred onto DQ by the NMI 146 and is deasserted ata time when DQ does not contain request information. Non-volatile memory150 may detect that DQ is no longer asserted and determine that therequest phase of the write transaction has been exited and thetransaction is entering a data phase.

Also at time 430 f. NMI 146 may transfer data onto DQ. The non-volatilememory 150 may acquire the data from DQ using a strobe that may beprovided on DQS by NMI 146. The data may include data to be written inthe non-volatile memory 150. At time 430 g, NMI 146 may completetransferring the data onto DQ.

At time 430 g. NMI 146 may deassert ACT which may indicate that the NMI146 no longer has ownership of DQ. After deasserting ACT, NMI 146 maytransfer a post-amble onto DQS, as indicated at times 430 g and 430 h.The non-volatile memory 150 may acquire the post-amble and determinethat the data phase of the write transaction has been exited.

At time 430 j, non-volatile memory 150 may write the data to a locationin the non-volatile memory 150 that may be identified by an address thatwas specified by the request. Afterwards, at time 430 k, non-volatilememory 150 may assert RRDY to indicate to the NMI 146 that thenon-volatile memory 150 is ready to send a response. At this point, thewrite transaction may enter the response phase.

The NMI 146 may detect that RRDY is asserted and, at time 430 m, maygrant ownership of DQ to the non-volatile memory 150 by assertingRGRANT. Non-volatile memory 150 may detect that RGRANT is asserted anddetermine that the non-volatile memory 150 has been granted ownership ofDQ. At times 430 n and 430 o non-volatile memory 150 may transfer apreamble onto DQS. NMI 146 may acquire the preamble and prepare toacquire a response on DQ. Preparing may include training, such asdescribed above.

At time 430 p, the non-volatile memory 150 may transfer the responseonto DQ. In addition, at time 430 q, non-volatile memory 150 may sendpadding information on DQ (indicated in diagram 400 as “P”). The paddinginformation may be used to “pad out” the response to a certain length(e.g., a certain number of bytes).

NMI 146 may use strobes provided on DQS by non-volatile memory 150 toacquire the response and padding information on DQ. NMI 146 may processthe response. Here, processing may include, for example, determiningwhether the response has indicate the request was performedsuccessfully.

At times 430 q and 430 r, non-volatile memory 150 may send a post-ambleon DQS. NMI 146 may receive the post-amble and determine that theresponse phase of the write transaction has been exited. Afterwards, attime 430 s, NMI 146 may deassert RGRANT to indicate that thenon-volatile memory 150 no longer has ownership of DQ.

In computing device 100 (FIG. 1). NMI 146 may be considered a host tonon-volatile memory 150 and non-volatile memory 150 may be considered aclient of NMI 146. This relationship may be established, for example,based on which entity may control ownership of DQ. As described above,the NMI 146 may take ownership of DQ without requesting ownership first.Non-volatile memory 150, on the other hand, asserts RRDY to requestownership of DQ and waits until the NMI 146 grants ownership before thenon-volatile memory 150 takes ownership of DQ. It may be said that NMI146 controls which entity has ownership of DQ. Thus, based on thisbehavior, it may be said that NMI 146 is a host to non-volatile memory150 which is a client of NMI 146.

Communication between NMI 146 and non-volatile memory 150 via bus 190may follow a protocol. The protocol may be subject to one or more rules.For example, the protocol may be subject to one or more of the followingrules;

-   -   1) RRDY assertion by non-volatile memory 150 may depend on        RGRANT being sampled by non-volatile memory 150 as being        deasserted;    -   2) RGRANT assertion by NMI 146 may depend on RRDY being sampled        by NMI 146 as being asserted along with ACT and RQRDY being        deasserted. Minimum assertion duration may be for a        predetermined number of clock cycles of a clock associated with        the NMI 146 (NMI clock). For example, NMI 146 may assert RGRANT        for a minimum of two clock cycles of the NMI clock;    -   3) The non-volatile memory 150 may start transmitting a preamble        on DQS after sampling RGRANT assertion for a predetermined        number of clock cycles of a clock associated with the        non-volatile memory 150 (non-volatile memory clock). For        example, non-volatile memory 150 may start transmitting a        preamble on DQS after sampling RGRANT assertion for one clock        cycle of the non-volatile memory clock;    -   4) RGRANT may be deasserted by NMI 146 before RRDY is        deasserted. Alternatively, RGRANT may be deasserted after the        NMI 146 detects RRDY has been deasserted;    -   5) RRDY deassertion may occur after a transaction has completed        or in response to NMI 146 regaining bus ownership before a        transaction has completed;    -   6) NMI 146 may begin sending a preamble on DQS after sampling        RRDY as being deasserted for a predetermined number of NMI clock        cycles (e.g., one NMI clock cycle). A predetermined time after        the preamble is sent, NMI 146 may begin sending information on        DQ;    -   7) After RGRANT is sampled as deasserted by non-volatile memory        150, RRDY may be deasserted by non-volatile memory 150. In        addition, non-volatile memory 150 may end transmitting        information on DQ and DQS. Transmission of the information may        be ended on a particular boundary associated with the        information (e.g., a 64-byte boundary). Deassertion of RRDY may        indicate, for example, an end of transmission by the        non-volatile memory 150;    -   8) RQRDY assertion may envelope information transmitted on DQ by        NMI 146. For example, RQRDY assertion may envelope command        information transmitted on DQ by NMI 146 in a read transaction;    -   9) RQRDY may be deasserted for a predetermined duration (e.g.,        for two NMI clocks). If request phases are back-to-back. RQRDY        may remain asserted and not be deasserted between the phases;    -   10) NMI 146 may tri-state DQ and/or DQS after a read        transaction's request phase has completed and/or after a write        transaction's data phase;    -   11) ACT assertion may depend on RGRANT and RRDY being        de-asserted; and/or    -   12) Deassertion of ACT may occur after a predetermined number of        NMI clock cycles. For example, deassertion of ACT may occur        after one clock cycle of the NMI clock.

FIGS. 5A-B illustrate a flow diagram of example acts, associated with aread transaction, that may be performed by a host, such as, for example,NMI 146. Referring to FIG. 5A, at block 510, an indication may be sentto a client that the host has a request to send. For example, supposethe host is NMI 146 and the client is non-volatile memory 150. At block510, NMI 146 may assert ACT to indicate to non-volatile memory 150 thatthe NMI 146 has a request to send to the non-volatile memory 150.

At block 520, an indication is sent to the client where the indicationindicates that a read request is being sent via bus. For example, NMI146 may assert RQRDY to indicate to non-volatile memory 150 that a readrequest is being sent to non-volatile memory 150 on DQ. At block 530, aread request may be sent to the client via the bus. For example, NMI 146may send the read request to non-volatile memory 150 via DQ.

At block 540, an indication that the client is ready to send informationmay be acquired. For example, the non-volatile memory 150 may receivethe read request and process it. Processing may include, for example,reading data from a location in the non-volatile memory 150 where thelocation may be identified based on an address that may be contained inthe read request. After the data is read, non-volatile memory 150 mayassert RRDY to indicate that the non-volatile memory 150 is ready tosend the data to the NMI 146.

At block 550 (FIG. 5B), an indication that the client has ownership ofthe bus may be sent. For example, NMI 146 may assert RGRANT to indicateto the non-volatile memory 150 that the non-volatile memory 150 hasownership of DQ. At block 560, information from the client may beacquired via the bus. For example, after detecting that that RGRANT hasbeen asserted, non-volatile memory 150 may begin sending the data to NMI146 via DQ and NMI 146 may read the data from DQ using, for example, astrobe signal sent by the non-volatile memory 150 on DQS. Moreover,non-volatile memory 150 may transfer response information to the NMI 146via DQ and the NMI 146 may read the response information from DQ, suchas described above.

At block 570, an indication may be acquired from the client thatinformation is not longer being sent from the client to the host via thebus. For example, after sending the response information, thenon-volatile memory 150 may send a post-amble on DQS. The post-amble mayindicate information is not longer being sent on DQ by the non-volatilememory 150.

At block 580, an indication may be sent that indicates that the clientno longer has ownership of the bus. For example, NMI 146 may deassertRGRANT to indicate to non-volatile memory 150 that the non-volatilememory 150 no longer has ownership of DQ.

FIGS. 6A-B illustrate a flow diagram of example acts, associated with aread transaction, that may be performed by a client. Referring to FIG.6A, at block 610, an indication may be acquired from a host that thehost has a request to send to the client. For example, suppose the hostis NMI 146 and the client is non-volatile memory 150. At block 610, NMI146 may assert ACT to indicate that the NMI 146 has a request to send tonon-volatile memory 150. Non-volatile memory 150 may detect that ACT isasserted and determine that the NMI 146 has a request to send to thenon-volatile memory 150.

At block 620, an indication may be acquired from the host that a readrequest is being sent on the bus. For example, NMI 146 may assert RQRDYto indicate to non-volatile memory 150 that a read request is being senton the DQ bus by the NMI 146. At block 630, the read request is acquiredfrom the host via the bus. For example, non-volatile memory 150 may readthe read request from DQ using, for example, a strobe signal sent by NMI146 on DQS.

At block 640, data may be read based on the read request. For example,the read request may include an address. The non-volatile memory 150 mayuse the address to identify a location in the non-volatile memory 150that contains the data. The non-volatile memory 150 may read the datafrom the identified location in the non-volatile memory 150.

At block 650 (FIG. 6B), an indication that the client is ready to sendinformation may be sent. For example, after reading the data from thenon-volatile memory 150, the non-volatile memory 150 may assert RRDY.NMI 146 may detect that RRDY has been asserted and determine that thenon-volatile memory 150 is ready to send the requested data.

At block 660, an indication that the client has ownership of the bus maybe acquired and information may be sent to the host via the bus. Forexample, NMI 146 may grant ownership of the DQ to the non-volatilememory 150 using RGRANT, as described above. After non-volatile memory150 determines it has ownership of DQ, non-volatile memory 150 may sendthe data via DQ to the NMI 146, such as described above.

At block 670, an indication that the information is no longer being senton the bus is sent. For example, the non-volatile memory 150 may send apost-amble to NMI 146 via DQS to indicate that information is no longerbeing sent on DQ.

At block 680, an indication may be acquired from the host that indicatesthat the client no longer has ownership of the bus. For example, NMI 146may deassert RGRANT to indicate to non-volatile memory 150 that thenon-volatile memory 150 no longer has ownership of DQ.

FIGS. 7A-B illustrate a flow diagram of example acts, associated with awrite transaction, that may be performed by a host. Referring to FIG.7A, at block 710, an indication that the host has a request to send maybe sent. For example, suppose the host is NMI 146 and the client isnon-volatile memory 150. At block 710, NMI 146 may assert ACT toindicate to non-volatile memory 150 that the NMI 146 has a request tosend to the non-volatile memory 150. Non-volatile memory 150 may detectthat ACT is asserted and determine that the NMI 146 has a request tosend.

At block 720, an indication that the request is being sent via the busis sent. For example, NMI 146 may assert RQRDY to indicate to thenon-volatile memory 150 that the request is being sent on the QD. Atblock 730, the request and information to be written is sent via thebus. For example, after asserting RQRDY, NMI 146 may send the request tothe non-volatile memory 150 via QD. After the request is sent, NMI 146may deassert RQRDY. NMI 146 may then send data to be written to thenon-volatile memory 150 via QD.

At block 740, an indication may be acquired where the indication mayindicate that a response is ready to be sent to the host from theclient. For example, after writing the data in the non-volatile memory150, non-volatile memory 150 may assert RRDY to request access to QD tosend a response to the NMI 146. NMI 146 may detect that RRDY is assertedand determine that the non-volatile memory 150 is ready to send aresponse.

At block 750 (FIG. 7B), an indication may be sent to the client thatindicates that the client has been granted ownership of the bus. Forexample, after detecting RRDY is asserted, the NMI 146 may assert RGRANTto grant ownership of the bus to the non-volatile memory 150.

At block 760, a response may be acquired via the bus. For example, thenon-volatile memory 150 may detect that RGRANT is asserted and determinethat the NMI 146 has granted the non-volatile memory 150 ownership ofQD. Non-volatile memory 150 may send the response to NMI 146 via QD. TheNMI 146 may receive the response from the QD, such as described above.

At block 770, an indication may be acquired that the response is nolonger being sent on the bus. For example, after sending the response,the non-volatile memory 150 may send a post-amble on QDS. NMI 146 maydetect the post-amble and determine that the response is no longer beingsent on the bus.

At block 780, an indication that the client no longer has ownership ofthe bus may be sent. For example, NMI 146 may deassert RGRANT toindicate to the non-volatile memory 150 that the non-volatile memory 150no longer has ownership of DQ.

FIGS. 8A-B illustrate a flow diagram of example acts, associated with awrite transaction, that may be performed by a client. Referring to FIG.8A, at block 810, an indication that the host has a request to send maybe acquired. For example, suppose the host is NMI 146 and the client isnon-volatile memory 150. The NMI 146 may assert ACT to indicate that theNMI 146 has a request to send. The non-volatile memory 150 may detectthat ACT is asserted and determine that the NMI 146 has a request tosend.

At block 820, an indication that a write request is being sent via thebus may be acquired and, at block 830, the write request and data may beacquired. For example, the NMI 146 may assert RQRDY to indicate that arequest is being sent on DQ. Non-volatile memory 150 may detect thatRQRDY is asserted and read the request from DQ, such as described above.NMI 146 may deassert RQRDY to indicate, for example, that a commandportion of the request has been sent and that the data portion of therequest is being sent on QD. Non-volatile memory 150 may detect thatRQRDY has been deasserted and read the data from DQ, such as describedabove.

At block 840, the data is written to the non-volatile memory. Forexample, after acquiring the request, non-volatile memory 150 mayprocess the request. Here, processing may include determining therequest is a write request. Non-volatile memory 150 may also identify alocation in non-volatile memory 150 to be written based on an addressthat may be contained in the request. After reading the data from DQ,the non-volatile memory 150 may write the data to the identifiedlocation in the non-volatile memory 150.

At block 850 (FIG. 8B), an indication may be sent that indicates that aresponse to the write request is ready to be sent. For example,non-volatile memory 150 may assert RRDY to indicate that thenon-volatile memory 150 has a response to send via DQ. NMI 146 maydetect that RRDY has been asserted and determine that the non-volatilememory 150 has a response to send.

At block 860, an indication may be acquired where the indication mayindicate that ownership of the bus has been granted to the client. Inaddition, at block 860 a response may be sent by the client to the host.For example, after NMI 146 determines that non-volatile memory 150 has aresponse to send, NMI 146 may assert RGRANT to grant ownership of DQ tonon-volatile memory 150. Non-volatile memory 150 may detect that RGRANThas been asserted and determine that the non-volatile memory 150 hasownership of DQ. After making this determination, non-volatile memory150 may send the response to NMI 146 via DQ, such as described above.

At block 870, an indication may be sent that indicates that the responseis no longer being sent on the bus. For example, non-volatile memory 150may send a post-amble on DQS to indicate that the response is no longerbeing sent on DQ.

At block 880, an indication may be acquired that indicates ownership ofthe bus is no longer granted to the client. For example, NMI 146 maydeassert RGRANT to indicate to non-volatile memory 150 that non-volatilememory 150 no longer has ownership of DQ. Non-volatile memory 150 maydetect that RGRANT is no longer asserted and determine that thenon-volatile memory 150 no longer has ownership of DQ.

FIG. 9 illustrates a block diagram of another example embodiment of acomputing device 900 that may implement techniques described herein.Referring to FIG. 9, computing device 900 may include various componentssuch as, for example, logic 920, primary storage 930, secondary storage950, one or more input devices 960, one or more output devices 970,and/or one or more communication interfaces 980.

It should be noted that FIG. 9 illustrates an example embodiment ofcomputing device 900. Other embodiments of computing device 900 mayinclude more components or fewer components than the componentsillustrated in FIG. 9. Further, the components may be arrangeddifferently than as illustrated in FIG. 9.

For example, in an embodiment of computing device 900, secondary storage950 may be contained at a remote site that provides “cloud” storage. Thesite may be accessible to computing device 900 via a communicationsnetwork, such as, for example, the Internet. A communication interface980 may be used to interface the computing device 900 with thecommunications network.

Also, it should be noted that features provided by various componentscontained in other embodiments of computing device 900 may bedistributed among the components differently than as described herein.

Computing device 900 may include an input/output (I/O) bus 910 that mayenable communication among components in computing device 900. Thecomponents may include, for example, logic 920, secondary storage 950,one or more input devices 960, one or more output devices 970, and/orone or more communication interfaces 980. The communication may involve,for example, transferring control signals and/or data between thecomponents via I/O bus 910. I/O busses that may be used to implement I/Obus 910 may include, for example, serial AT attachment (SATA),peripheral component interconnect (PCI), PCI express (PCI-e), universalserial bus (USB), small computer system interface (SCSI), serialattached SCSI (SAS), or some other I/O bus.

Input devices 960 may include one or more devices that may be used toinput information into computing device 900. The devices may include,for example, a keyboard, computer mouse, microphone, camera, trackball,gyroscopic device (e.g., gyroscope), mini-mouse, touch pad, stylus,graphics tablet, touch screen, joystick (isotonic or isometric),pointing stick, accelerometer, palm mouse, foot mouse, puck, eyeballcontrolled device, finger mouse, light pen, light gun, neural device,eye tracking device, steering wheel, yoke, jog dial, space ball,directional pad, dance pad, soap mouse, haptic device, tactile device,neural device, multipoint input device, discrete pointing device, and/orsome other input device.

The information may include spatial (e.g., continuous,multi-dimensional) data that may be input into computing device 900using, for example, a pointing device, such as a computer mouse. Theinformation may also include other forms of data, such as, for example,text that may be input using a keyboard.

Output devices 970 may include one or more devices that may outputinformation from computing device 900. The devices may include, forexample, a cathode ray tube (CRT), plasma display device, light-emittingdiode (LED) display device, liquid crystal display (LCD) device, vacuumflorescent display (VFD) device, surface-conduction electron-emitterdisplay (SED) device, field emission display (FED) device, hapticdevice, tactile device, printer, speaker, video projector, volumetricdisplay device, plotter, touch screen, and/or some other output device.

Output devices 970 may be directed by, for example, logic 920, to outputthe information from computing device 900. Outputting information on anoutput device 970 may include, for example, presenting (e.g.,displaying, printing) the information on the output device 970. Theinformation may include, for example, text, graphical user interface(GUI) elements (e.g., windows, widgets, and/or other GUI elements),audio (e.g., music, sounds), and/or other information that may beoutputted by output devices 970.

Communication interfaces 980 may include logic for interfacing computingdevice 900 with, for example, one or more communications networks andenable computing device 900 to communicate with one or more entities(e.g., nodes) coupled to the communications networks. The communicationsnetworks may include, for example, the Internet, wide-area networks(WVANs), local area networks (LANs), 3G and/or 4G (e.g., 4G long-termevolution (LTE)) networks.

Communication interfaces 980 may include one or more transceiver-likemechanisms that may enable computing device 900 to communicate withentities coupled to the communications networks. Examples ofcommunication interfaces 980 may include a built-in network adapter,network interface card (NIC), Personal Computer Memory CardInternational Association (PCMCIA) network card, card bus networkadapter, wireless network adapter, Universal Serial Bus (USB) networkadapter, modem, and/or other device suitable for interfacing computingdevice 100 to a communications network.

Primary storage 930 and/or secondary storage 950 may include one or morestorage modules such as, for example, storage modules described above.Computing device 900 may include a memory bus 990 that may enableinformation stored in primary storage 930, to be transferred betweenlogic 920 and primary storage 930. The information may include, forexample, computer-executable instructions and/or data that may beexecuted, manipulated, and/or otherwise processed by logic 920.

Primary storage 930 may be accessible to logic 920 via memory bus 990.Primary storage 930 may be a tangible non-transitory storage that maystore information. The information may include computer-executableinstructions and/or data that may implement operating system (OS) 932and application (APP) 934 or parts thereof. The information may beexecuted, interpreted, manipulated, and/or otherwise processed by logic920. Primary storage 930 may be implemented using one or more memorydevices that may store the information. The memory devices may includevolatile and/or non-volatile memory devices such as described above.

OS 932 may be a conventional operating system that may implement variousconventional operating system functions that may include, for example,(1) scheduling one or more portions of APP 934 to run on (e.g., beexecuted by) the logic 920, (2) managing primary storage 930, and (3)controlling access to various components in computing device 900 (e.g.,input devices 960, output devices 970, communication interfaces 980,secondary storage 950) and information received and/or transmitted bythese components.

Examples of operating systems that may be used to implement OS 932 mayinclude the Linux operating system, Microsoft Windows operating system,the Symbian operating system, Mac OS operating system, and the Androidoperating system. A distribution of the Linux operating system that maybe used is Red Hat Linux available from Red Hat Corporation. Raleigh,N.C. Versions of the Microsoft Windows operating system that may be usedinclude Microsoft Windows Mobile, Microsoft Windows 8, Microsoft Windows7, Microsoft Windows Vista, and Microsoft Windows XP operating systemsavailable from Microsoft Inc., Redmond, Wash. The Symbian operatingsystem is available from Accenture PLC. Dublin, Ireland. The Mac OSoperating system is available from Apple, Inc., Cupertino, Calif. TheAndroid operating system is available from Google, Inc., Menlo Park,Calif.

APP 934 may be a software application that may execute under control ofOS 932 on computing device 900. APP 934 and/or OS 932 may containprovisions for processing transactions that may involve storinginformation in secondary storage 950. These provisions may beimplemented using data and/or computer-executable instructions containedin APP 934 and/or OS 932.

Secondary storage 950 may be a tangible non-transitory storage that maystore information for computing device 900. The information may include,for example, computer-executable instructions and/or data. Theinformation may be executed, interpreted, manipulated, and/or otherwiseprocessed by logic 920.

Secondary storage may include one or more storage devices 952 that maystore the information. The storage devices 952 may be accessible tologic 920 via I/O bus 910. The storage devices 952 may be volatile ornon-volatile. Examples of storage devices 952 may include magnetic diskdrives, optical disk drives, random-access memory (RAM) disk drives,flash drives, solid-state disks (SSDs), and/or hybrid drives. Theinformation may be stored on one or more tangible non-transitorycomputer-readable media contained in the storage devices 952. Examplesof tangible non-transitory tangible computer-readable media that may becontained in the storage devices may include magnetic discs, opticaldiscs, volatile memory devices, and/or non-volatile memory devices.

Logic 920 may include processing logic (PL) 924 for interpreting,executing, and/or otherwise processing information. The information mayinclude information that may be stored in primary storage 930 and/orsecondary storage 950. In addition, the information may includeinformation that may be acquired (e.g., read, received) by one or moreinput devices 960 and/or communication interfaces 980.

PL 924 may include a variety of heterogeneous hardware. For example, thehardware may include some combination of one or more processors,microprocessors, field programmable gate arrays (FPGAs), applicationspecific instruction set processors (ASIPs), application specificintegrated circuits (ASICs), complex programmable logic devices (CPLDs),graphics processing units (GPUs), and/or other types of processing logicthat may, for example, interpret, execute, manipulate, and/or otherwiseprocess the information. Logic 920 may comprise a single core ormultiple cores.

Logic 920 may also include interface logic (IL) 924 that may interfaceprocessing logic with primary storage 930. IL 924 may include provisionsfor transferring information to be transferred between primary storage930 and logic 920 via bus 990. The information may be transferredutilizing various techniques, such as techniques described above.

For example, in an embodiment, primary storage 930 may includenon-volatile memory that may be accessible to logic 920 via bus 990. IL924 may contain logic that may be used to communicate informationbetween the non-volatile memory contained in primary storage 930 and PL924 via bus 990 using various techniques, such as techniques describedabove. The logic may contained in IL 924 may include, for example, statemachines, bus transceivers, registers, and/or other logic that may beused to enable the transfer of the information between the non-volatilememory and PL 924. The information may include, for example, requestsand/or data, such as described above.

The foregoing description of embodiments is intended to provideillustration and description, but is not intended to be exhaustive or tolimit the invention to the precise form disclosed. Modifications andvariations are possible in light of the above teachings or may beacquired from practice of the invention. For example, while a series ofacts has been described above with respect to FIGS. 5A-B, 6A-B, 7A-B,and 8A-B, the order of the acts may be modified in otherimplementations. Further, non-dependent acts may be performed inparallel.

Also, the term “user”, as used herein, is intended to be broadlyinterpreted to include, for example, a computing device (e.g., fixedcomputing device, mobile computing device) or a user of a computingdevice, unless otherwise stated.

It will be apparent that one or more embodiments, described herein, maybe implemented in many different forms of software and/or hardware.Software code and/or specialized hardware used to implement embodimentsdescribed herein is not limiting of the invention. Thus, the operationand behavior of embodiments were described without reference to thespecific software code and/or specialized hardware—it being understoodthat one would be able to design software and/or hardware to implementthe embodiments based on the description herein.

Further, certain features of the invention may be implemented usingcomputer-executable instructions that may be executed by processinglogic, such as, for example, processing logic 130 or processing logic922. The computer-executable instructions may be stored on one or morenon-transitory tangible computer-readable storage media. The media maybe volatile or non-volatile and may include, for example, DRAM, SRAM,flash memories, removable disks, non-removable disks, and so on.

No element, act, or instruction used herein should be construed ascritical or essential to the invention unless explicitly described assuch. Also, as used herein, the article “a” is intended to include oneor more items. Where only one item is intended, the term “one” orsimilar language is used. Further, the phrase “based on” is intended tomean “based, at least in part, on” unless explicitly stated otherwise.

It is intended that the invention not be limited to the particularembodiments disclosed above, but that the invention will include any andall particular embodiments and equivalents falling within the scope ofthe following appended claims.

What is claimed is:
 1. A method comprising: sending an indication that arequest is being sent, the indication being sent to a non-volatilememory via a bus between a memory interface and the non-volatile memory;sending a preamble to the non-volatile memory via the bus, the preamblefor use by the non-volatile memory to prepare to acquire the requestfrom the bus; sending the request to the non-volatile memory via thebus, the request including an address for identifying a location in thenon-volatile memory containing data to be read; acquiring an indicationvia the bus that the non-volatile memory is ready to send information;sending an indication via the bus that access to the bus has beengranted to the non-volatile memory; and acquiring the information fromthe non-volatile memory via the bus, the information including the data.2. The method of claim 1, wherein the request includes a command thatindicates that a read operation is to be performed by the non-volatilememory.
 3. The method of claim 1, further comprising: sending anindication via the bus that the memory interface has a request to send.4. The method of claim 1, further comprising: acquiring a strobe signalfrom the bus; and acquiring the information from the bus using theacquired strobe signal.
 5. The method of claim 1, wherein the busincludes a plurality of wires and, wherein the request is sent to thenon-volatile memory and the information is acquired from thenon-volatile memory on the same wire of the plurality of wires.
 6. Themethod of claim 1, further comprising: sending an indication via the busthat indicates the non-volatile memory has ownership of the bus.
 7. Themethod of claim 1, further comprising: acquiring an indication from thebus that the non-volatile memory is no longer sending the information onthe bus.
 8. The method of claim 7, wherein the indication that thenon-volatile memory is no longer sending the information on the busincludes a post-amble.
 9. The method of claim 7, wherein the busincludes a plurality of wires and wherein the information sent by thenon-volatile memory is acquired on a first wire of the plurality ofwires and the indication that the non-volatile memory is no longersending the information is acquired on a second wire of the plurality ofwires.
 10. A method comprising: sending an indication that a request isbeing sent, the indication being sent to a non-volatile memory via a busbetween a memory interface and the non-volatile memory; sending apreamble to the non-volatile memory via the bus, the preamble for use bythe non-volatile memory to prepare to acquire the request from the bus;sending the request to the non-volatile memory via the bus, the requestincluding an address for use in identifying a location in non-volatilememory to be written; sending data to be written to the non-volatilememory via the bus; acquiring an indication that the non-volatile memoryhas a response to send to the memory interface via the bus; grantingaccess to the bus to the non-volatile memory, the access being grantedvia the bus; and acquiring a response from the non-volatile memory viathe bus, the response including a status associated with the request.11. The method of claim 10, wherein the bus includes a plurality ofwires, and wherein the request is acquired and the data is sent on thesame wire of the plurality of wires.
 12. An apparatus comprising: aninterface to a non-volatile memory; and processing logic to: send anindication that a request is being sent, the indication being sent to anon-volatile memory via a bus, send a preamble to the non-volatilememory via the bus, the preamble for use by the non-volatile memory toprepare to acquire the request from the bus, send the request to thenon-volatile memory via the bus, the request including an address foridentifying a location in the non-volatile memory containing data to beread, acquire an indication via the bus that the non-volatile memory isready to send information, send an indication via the bus that access tothe bus has been granted to the non-volatile memory, send theinformation from the non-volatile memory via the bus, the informationincluding the data.
 13. The apparatus of claim 12, wherein the requestincludes a command that indicates that a read operation is to beperformed by the non-volatile memory.
 14. The apparatus of claim 12,wherein the processor logic is further configured to: acquire a strobesignal from the bus; and acquire the information from the bus using theacquired strobe signal.
 15. The apparatus of claim 12, wherein the busincludes a plurality of wires and, wherein that read request is sent andthe information from the non-volatile memory is acquired on the samewire of the plurality of wires.
 16. The apparatus of claim 12, whereinthe processor logic is further configured to: send an indication via thebus that indicates the non-volatile memory has ownership of the bus. 17.The apparatus of claim 12, wherein the processor logic is furtherconfigured to: acquire an indication from the bus that the non-volatilememory is no longer sending the information on the bus.
 18. Theapparatus of claim 17, wherein the indication that the non-volatilememory is no longer sending the information on the bus includes apost-amble.
 19. The apparatus of claim 17, wherein the bus includes aplurality of wires and wherein the information sent by the non-volatilememory is acquired on a first wire of the plurality of wires and theindication that the non-volatile memory is no longer sending theinformation is acquired on a second wire of the plurality of wires. 20.The apparatus of claim 12, further comprising: the non-volatile memorycommunicatively coupled to the interface; a volatile memorycommunicatively coupled to the processing logic; a host controllercommunicatively coupled to a volatile memory interface; and a buscommunicatively coupled to the non-volatile memory interface and thenon-volatile memory.